Dark Energy and Matter Evolution from Lensing Tomography
Abstract
Reconstructed from lensing tomography, the evolution of the dark matter density field in the well-understood linear regime can provide model-independent constraints on the growth function of structure and the evolution of the dark energy density. We examine this potential in the context that high-redshift cosmology has in the future been fixed by CMB measurements. We construct sharp tests for the existence of multiple dark matter components or a dark energy component that is not a cosmological constant. These functional constraints can be transformed into physically motivated model parameters. From the growth function, the fraction of the dark matter in a smooth component, such as a light neutrino, may be constrained to a statistical precision of sigma(f)= 0.0006 fsky-1/2 by a survey covering a fraction of sky fsky with redshift resolution dz=0.1. For the dark energy, a parameterization in terms of the present energy density OmegaDE, equation of state w and its redshift derivative w', the constraints correspond to sigma(w)=0.016 fsky-1/2 and a degenerate combination of the other two parameters. For a fixed OmegaDE, sigma(w') = 0.046 fsky-1/2; for OmegaDE marginalized, sigma(w') = 0.069 fsky-1/2.
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